DE4433712A1 - Refrigerated cabinets with at least two compartments of different temperatures - Google Patents

Description

The invention relates to a refrigerator with at least two compartments different temperatures, their evaporators together with a compressor and a condenser in a cold circle and from the compressor when signaling a cooling requirement for the compartments with liquid refrigerant be acted upon, the contributing to the refrigeration Refrigerant volume is controllable.

DE-OS 35 08 805 is a two-temperature refrigerator known, the thermally separated subjects under different temperature cooled by an evaporator are in a refrigeration cycle with a single compressor lie and controlled by these as heatable chokes trained control bodies depending on the cooling requirements in the fa Either one after the other or simultaneously liquid refrigerant can be applied. To be enough to provide the amount of refrigerant in the latter case and at the same time a refrigerant overfill in single operation Avoiding the evaporator is on the pressure side of the compressor a collector downstream, which has a dead end-like Lich trained connecting line to the pressure line of the Ver is connected more densely and which a heating element for  Expulsion of the liquid stored in its collection space Refrigerant is assigned. In the event that for the subjects Refrigeration demand is signaled with a timed advance run the collector before commissioning the compressor assigned heating element activated, in order to then the saved supplied liquid refrigerant to the refrigerant circuit ren.

Another two-temperature cooling device is from DE-OS 40 20 537 known whose thermally separated calves compartments of different temperatures connected in series in within one equipped with a single compressor Refrigeration circuit and depending on the cooling demand, controlled by lockable throttles each individually or together can be acted upon with refrigerant, the amount of refrigerant is matched to the filling quantity of the two evaporators. Is the cooling requirement signaled only for one of the two cooling compartments is available in the entire refrigeration circuit amount of refrigerant to overfill one individually to avoid operating evaporator by using an over one Restrict the throttling device to tap the condenser divided according to the capacity of this evaporator. In follow the tap of the condenser will only be in front of this Tapping section from that through the compressor circulated refrigerant flows.

Both refrigeration circuits that have become known from the prior art allow a need based on the respective evaporator Tailored control of the amount of refrigerant, but haf tet the disadvantage of the system known from DE-OS 35 08 805 assumes that an ener for both compartments when there is a refrigeration request Time-consuming provision for heating the collector before starting the compressor is necessary to the liquid  Expel refrigerant from the collector and the refrigeration cycle to provide. The known from DE-OS 40 20 537 Technology is disadvantageous in that the condenser at a refrigeration request from only one of the cooling compartments at all times proportionate flow of refrigerant and thus its surface area required for heat exchange significantly reduced is what the compressor running times and thus the energy Increase the device's energy consumption significantly.

The invention has for its object in a refrigerator to propose measures according to the preamble of claim 1 conditions, based on which the op the maximum amount of refrigerant is always provided and at the same time at the same time avoided the disadvantages of the prior art are.

This object is achieved according to the invention in that Control of the amount of refrigerant in the refrigeration circuit of the compressor serve on the pressure side to hold liquid refrigerant the reservoir is connected downstream, which is by a deflector can be coupled into the refrigeration circuit, with the on coupling of the refrigerants caused by the compressor flow is at least substantially over the reservoir.

The solution according to the invention ensures that at a refrigeration requirement for all subjects Amount of refrigerant immediately after signaling the cold available to the refrigeration circuit without time reserve stands. Furthermore, the entire surface of the condenser is always gers acted as a heat exchange surface, so that esp. at un operation of the refrigeration circuit, the compressor running times and  thus the energy consumption of the refrigerator is significantly reduced are. In addition, energy-intensive heaters can There is no need to expel the refrigerant from the collector.

According to a further preferred embodiment of the object of the invention it is provided that that for receiving liquid refrigerant reservoir and this in the Coupling the refrigerant circuit is able to divert the Condenser is connected downstream.

The advantage of such a solution is on the one hand that on expensive thermal insulation measures to prevent of the heat flow from the compressor to the collector to the collector function, namely the condensation of the gas phase existing refrigerant, ensure, as far as possible can fall. On the other hand, such an execution the refrigerant in the liquid phase before and is therefore immediately available for refrigeration.

According to an alternative embodiment of the object the invention with which an additional possibility ge is to create constructive countermeasures that may arise to take into account the refrigerator units, it is provided that the reservoir used to hold liquid refrigerant and the order to integrate it into the refrigeration cycle steering element between the compressor and the condenser is arranged.

According to a further preferred embodiment of the counter state of the invention it is provided that the deflector for holding liquid refrigerant reservoir is connected upstream on the input side.  

Such a solution is a direct redirection of the Refrigerant without the formation of additional, not to cold funds storage provided.

It is particularly easy to redirect the refrigerant flow through the deflector, if after a next advantageous embodiment of the subject of the invention it is provided that the deflector as a 3/2-way valve is trained.

A 3/2-way valve is particularly expedient, if after a next preferred embodiment of the counter state of the invention is provided that the 3/2-way valve as a bistable, electrically controllable solenoid valve is trained.

The magnet is particularly precisely timed and controlled as required valve if according to a further preferred embodiment the object of the invention is provided that the elek Electrically controlled solenoid valve value switching depending on the in the subject with the higher Storage temperature by a temperature sensor and temperature controlled by the evaluation circuit is controlled.

According to a further particularly advantageous embodiment of the The object of the invention is that for cooling of compartments of different temperature serving evaporators within the refrigeration circuit connected in series to each other are arranged and a cold falling in the refrigerant flow direction have performance.  

According to an alternative embodiment of the object the invention provides that for cooling the compartments different temperature evaporators inside the refrigeration circuit arranged in parallel to each other are.

The invention is in the following description based on egg nes shown in simplified form in the accompanying drawing Three-temperature cooling unit explained. Show it:

Fig. 1 is a three-temperature zones exhibiting household refrigerator having superposed, thermally separated from one another and closable by separate doors subjects in space pictorial depicting lung from the front,

Fig. 2 shows a schematic representation of the cooling circuit serving the cooling circuit with an electronics provided for its re regulation.

In Fig. 1, a household cooling device 10 is shown, on the heat-insulating housing 11 three doors 12 to 14 are pivoted about vertical axes of rotation. This the NEN for closing one above the other, produced by two spaced-apart partitions 15 and 16 and thermally separated from them compartments 17 to 19 , which have different storage temperatures. Of the subjects 17 to 19 the overhead, closable with the door 12 compartment 17 as a normal refrigerating compartment, which is middle, separated therefrom by the intermediate wall 15 and coverable by the door 13 compartment 18 is formed as a cold storage compartment, while the underlying, through the intermediate wall 16 from Cold storage compartment 18 thermally separated compartment 19 serves as a freezer compartment and can be closed with the door 14 . The prevailing subject-specific storage temperature in the individual compartments 17 to 19 is generated and maintained by a single refrigeration circuit 20 .

As can be seen in particular from FIG. 2, the refrigeration circuit 20 is equipped to maintain the temperature in the individual compartments 17 to 19 with three evaporators 21 to 23 arranged in series within the refrigeration circuit and equipped with different cooling capacities, of which the highest cooling capacity evaporator 21 is assigned to the freezer compartment 19 and has an injection point for the refrigerant. The freezer evaporator fer 21 is connected on the output side in the direction of refrigerant flow to the evaporator 22 used to cool the cold storage compartment 18 , to which the normal refrigeration compartment 17 is assigned, the evaporator 23 having the lowest cooling capacity is connected. This is coupled on the outlet side to the suction side of a refrigerant compressor 24 , which pressure-side in the refrigerant flow direction is connected to a condenser 25 , which is arranged, for example, on the rear of the housing 11 facing away from the doors 12 to 14 . The condenser 25 is followed on the output side by a dryer cartridge 26 equipped with hygroscopic material, which serves to absorb the residual water content arising from the liquid refrigerant during the filling process of the cooling circuit. The dryer cartridge 26 is connected on the output side to the input of a deflection member 27 . In the present case, this is designed as a bistable 3/2-way solenoid valve which, in its switching position 1, produces a flow path for the refrigerant between the outlet of the drying cartridge 26 and the inlet designed as an injection point of the freezer compartment evaporator 21 . In its other switching position 0, the solenoid valve 27 connects the output of the dryer cartridge 26 to the input of a reservoir 28 for the reception of liquid refrigerant, which is connected on the output side to the coolant line leading to the freezer evaporator 21, which can be controlled via the switching position 1 of the solenoid valve 27 is so that via the solenoid valve 27, the reservoir 28 can be coupled into the refrigerant flow.

The control signals changing the switching positions of the solenoid valve 27 are generated by a not described in an individual evaluation and control electronics 30 , and are fed via a signal line 31 to the solenoid valve 27 . Furthermore, the prevailing in the normal cooling compartment 17 or in the cold storage compartment 18 is detected via the evaluation and control electronics 30 , whereby in both compartments a NTC sensor formed, the air temperature sensing sensor element 32 is provided, each of which Via a signal line 33 or 34 for data transmission to the evaluation and control electronics 30 is connected to the latter. The evaluation and control electronics 30 is also used to control a fan 35 which circulates the internal clearance in the cold storage compartment 18 and which is connected for the purpose of control to a control line 36 with the evaluation and control electronics 30 , via which the compressor 24 is also operated is controlled, a control line 37 connecting the evaluation and control electronics 30 to the compressor 24 being provided for this purpose.

When the cooling device 10 is in operation, the operation of the only compressor 24 arranged in its cooling circuit 20 is determined by the storage temperature prevailing in the cold storage compartment 18 and detected by the sensor element 32 arranged therein, the voltage signals thereof corresponding via the signal line 34 of the evaluation and control electronics 30 are led through which the compressor 24 is activated or deactivated via the control line 37 when reaching the temperature limit values for the storage temperature in the cold storage compartment 18 . The amount of liquid refrigerant circulated by the controlled compressor 24 in the refrigeration circuit 20 is dependent on the prevailing in the cooling compartment 17 , detected by the NTC sensor and transmitted via the signal line 33 of the evaluation and control electronics 30 , this being controlled when the temperature falls below one Predetermined Temperaturgren ze in the refrigerator 17, the solenoid valve 27 switched over the signal line 31 in its switching position 1, so that the reservoir 28 serving as a liquid refrigerant reservoir is no longer flowed through by the refrigerant. As a result, the reservoir 28 becomes colder than the condenser 25 connected upstream of it, counter to the refrigerant flow direction, as a result of which liquid refrigerant accumulates in the reservoir 28 , which visually corresponds to its capacity at least to the liquid volume of the refrigerant circuit 20 for temperature control of the storage compartments to be withdrawn from the amount of liquid refrigerant. In this way, the refrigeration circuit 20 is operated underfilled, such an underfilling, in particular at the last position of the evaporator series connection, makes the cooling compartment evaporator 23 noticeable, which is depleted of liquid refrigerant due to the solenoid valve position, so that the temperature in the normal cooling compartment 17 rises . If the temperature in the normal cooling compartment 17 exceeds the upper temperature limit due to the depletion of liquid refrigerant taking place in the evaporator 23 , this is signaled with the aid of the NTC sensor 32 which detects the storage temperature of the evaluation and control electronics 30 , whereupon the latter solenoid valve 27 controls in its switch position 0.

In this switch position, the reservoir 28 is integrated in the cooling circuit 20 and thus flows through so that the amount of liquid refrigerant accumulated therein enters the cooling circuit 20 in the cold and is available for cooling the storage compartments 17 to 19 of the cooling device 10 .

Contrary to the embodiment described above, it can also be provided accordingly as shown by dashed lines, accordingly an alternative embodiment of the object of the invention, that the solenoid valve serving as deflector 27 together with the reservoir 28 which can be coupled into the refrigeration circuit 20 is connected upstream of the condenser 25 .

Instead of the evaporator ( 21 , 22 , 23 ) arranged in series in the refrigeration circuit 20 , the invention can also be applied to evaporators connected in parallel, with a corresponding circuit with electrically controllable solenoid valves being shown for their separate loading with refrigerant.

Claims (9)

1. refrigeration cabinets with at least two compartments of different temperatures, the evaporators of which are located together with a compressor and a condenser in a refrigerant circuit and are acted upon by the compressor with a signaling of a refrigeration requirement for the compartments with liquid refrigerant, the amount of refrigerant contributing to refrigeration being controllable is characterized in that, to control the amount of refrigerant in the refrigerant circuit ( 20 ), the compressor ( 24 ) on the pressure side is followed by a servo ( 28 ) for receiving liquid refrigerant, which is by a deflecting member ( 27 ) into the refrigerant circuit ( 20 ). can be coupled in, with the coupling of the refrigerant flow caused by the compressor ( 24 ), at least essentially, via the reservoir ( 28 ). 2. Refrigerating cabinet according to claim 1, characterized in that the serving for receiving liquid refrigerant Re servoir ( 28 ) and this in the refrigerant circuit ( 20 ) to be coupled deflector ( 27 ) is connected downstream of the condenser ( 25 ). 3. Refrigerated cabinet according to claim 1, characterized in that the serving for receiving liquid refrigerant Re servoir ( 28 ) and for its integration into the refrigerant medium circuit ( 20 ) serving deflector ( 27 ) between the compressor ( 24 ) and the condenser ( 25 ) is arranged. 4. Refrigerator cabinet according to one of claims 1 to 3, characterized in that the deflecting member ( 27 ) is upstream of the reservoir ( 28 ) serving to hold liquid refrigerant. 5. Refrigerated cabinet according to one of claims 1 to 4, characterized in that the deflecting member ( 27 ) is designed as a 3/2-way valve. 6. Refrigerated cabinet according to one of claims 1 to 5, characterized in that the 3/2-way valve is designed as a bistable electrically controllable solenoid valve ( 27 ). 7. Refrigerated cabinet according to claim 6, characterized in that the electrically controllable solenoid valve ( 27 ) by an electrical evaluation circuit ( 30 ) in dependence on the in the compartment ( 23 ) with the higher storage temperature by a temperature sensor ( 32 ) detected and by the evaluation circuit ( 30 ) rated temperature is controlled. 8. Refrigerated cabinet according to claim 1, characterized in that the cooling surfaces ( 17 , 18 , 19 ) serving different temperature evaporators ( 21 , 22 , 23 ) within half of the refrigeration circuit ( 20 ) are arranged in series with one another and one in Refrigerant flow direction have falling cooling capacity. 9. Refrigerating cabinet according to claim 1, characterized in that the evaporators ( 21 , 22 , 23 ) serving to cool the compartments ( 17 , 18 , 19 ) differing temperatures are arranged within half of the refrigeration circuit in parallel with one another.